DE102018003508A1 - Electrofluidic aggregate and method of operation - Google Patents

Abstract

short version
Task: The functions of a reciprocating pump and a valve should be connected in one unit. In particular, the pump and the valve should cooperate so that few line connections are required.
Solution: A pump unit (2) and a valve (3) are arranged on a same center line (10) and use a bearing rod (5) together for movably supporting a first magnet armature (7) actuating a displacer device (6) of the pump unit (2). on the one hand and a second armature (9) of the valve (3) actuating a group of closing bodies (8) on the other hand.
Application: Preferably for monitoring tank systems.

Description

The invention relates to an electro-fluidic unit, which consists of at least an electro-fluidic pump unit and an electro-fluidic valve, according to the preamble of the first claim, and four methods for operating the unit.

State of the art:

Are known reciprocating pumps, including those with a drive by an electromagnet. Even valves that are driven by an electromagnet are known and widely used. Furthermore, units are known which consist of a pump and at least one valve. Such aggregates are expensive to produce.

Task:

It is an aggregate will be described that combines the functions of a reciprocating pump and a valve and is inexpensive to produce in large quantities. In particular, the pump and the valve should cooperate so that few line connections are required.

Solution:

The objects directed to the device are achieved by the features of the first claim, advantageous developments are specified in the dependent claims 2 to 10, the last four claims describe methods for operating the device according to the invention.

The electrofluidic aggregate according to the invention contains at least one electro-fluidic pump unit and one electrofluidic valve. Both the pump unit and the valve are each actuated by an electromagnet.
The pump unit and the valve are arranged on a same center line and use a bearing rod together for the movable mounting of a displacer of the pump unit actuated first armature on the one hand and a group of closing bodies actuated second armature of the valve on the other.

Preferably, the bearing rod is designed as a tube, which fluidly connects the displacement device of the pump unit with one of the fluidic connections inlet or outlet of the unit.

In a first embodiment, the valve in the de-energized state of the associated solenoid fluidly bypasses the inlet of the unit with the outlet of the unit in bypassing the pump unit, wherein said connection is closed in the energized state of the electromagnet.

In a second embodiment, the valve in the energized state of the associated electromagnet, bypassing the pump unit fluidly connects the inlet of the unit with the outlet of the unit, wherein said connection is closed in the de-energized state of the electromagnet.

Advantageously, the pump unit has a directly or indirectly actuated by the first solenoid bellows, which acts as a fluidic displacement device. In this case, a return spring counteracts the force of the electromagnet, and at a suitable frequency of the drive pulses to the electromagnet, the spring-mass system, which consists of the return spring and the armature of the electromagnet, with the drive pulses in resonance.

Alternatively, the pump unit has a fluidic displacement device, which consists of at least one cylinder and a piston.

Further advantageously, the pump unit has an inlet valve, which consists of a valve seat and a valve body, wherein the valve body has a highly elastic disc and a centrally arranged holder.

Also advantageously, the pump unit also has an outlet valve, which consists of a valve seat and a valve body, wherein the valve body has a highly elastic disc and a centrally disposed holder.

The arrangement of the inlet valve and the outlet valve depends on whether the unit in the connected line to a tank or other device to generate an overpressure or a negative pressure. The fact that the electro-fluidic unit is suitable for both purposes, the valves mentioned must be installed in the appropriate orientation.

Advantageously, the electro-fluidic aggregate includes a pressure sensor connected to the outlet of the unit.

Also advantageously, the electrofluidic assembly includes a temperature sensor connected to the outlet of the unit.

• • am Auslass eine fluidische Druckdifferenz aufgebaut wird, indem bei geschlossenem Ventil der Elektromagnet des Pumpenaggregats getaktet bestromt wird, wobei der Magnetanker die Verdrängereinrichtung entsprechend bewegt und wobei Fluid gefördert wird und dabei der Gasdruck in einem angeschlossenen Tank erhöht oder abgesenkt wird,
• • die getaktete Bestromung des Elektromagneten des Pumpenaggregats beendet wird und das Ventil durch eine Bestromung seines Elektromagneten geschlossen gehalten wird,
• • ein Druckverlauf in einem angeschlossenen Tank gemessen wird, indem ein an den Auslass oder an die Zuleitung zum Tank angeschlossener Drucksensor den Verlauf des Drucks im Tank an die elektrische Steuerung übermittelt, wobei in der elektrischen Steuerung der Verlauf des Drucks aufgezeichnet wird,
• • nach einer vorgegebenen Zeit Tv die Messung und Aufzeichnung eines zweiten Druckverlaufs vorgenommen wird, wobei sich die Zeitdauer Tv nach der Größe des angeschlossenen Tanks richtet,
• • die beiden Druckverläufe miteinander verglichen werden und aus dem Unterschied der beiden Druckverläufe auf die Dichtheit des Tanks geschlossen wird,
• • der Druck im Tank (32) abgebaut wird, das Ventil (3) geöffnet wird, indem der zugehörige Elektromagnet (4) stromlos geschaltet wird.

In order to operate the electro-fluidic unit according to the invention, an electrical controller connected to the electro-fluidic unit controls the electromagnets so that

• A fluidic pressure difference is built up at the outlet, in that, when the valve is closed, the electromagnet of the pump unit is energized in a clocked manner, wherein the magnet armature moves the displacer accordingly and fluid is conveyed, thereby increasing or decreasing the gas pressure in a connected tank,
• • the clocked energization of the electromagnet of the pump unit is stopped and the valve is kept closed by energizing its electromagnet,
• • a pressure profile in a connected tank is measured by a pressure sensor connected to the outlet or to the supply line to the tank communicating the course of the pressure in the tank to the electrical control, wherein the course of the pressure is recorded in the electrical control,
• After a predetermined time Tv, the measurement and recording of a second pressure curve is carried out, the time Tv being dependent on the size of the connected tank,
• • the two pressure gradients are compared with each other and it is concluded from the difference of the two pressure gradients on the tightness of the tank,
• • the pressure in the tank ( 32 ), the valve ( 3 ) is opened by the associated electromagnet ( 4 ) is de-energized.

The method of operation of the electrofluidic aggregate can be improved by also measuring and recording the temperature of the fluid at the outlet or in the supply line to the tank by means of a temperature sensor during each measurement and recording of the pressure in the tank, in which case the comparison of the pressure profiles Also, the temperature curves are used to calculate a corrected course of the pressure curves using the general gas equation.

The method for operating an electro-fluidic unit can be further improved in the sense of an OBD (on-board diagnosis) by the electrical control monitors the electro-fluidic unit for its intended function, both the course of energization of the electromagnet of the pump unit and the course of the be measured by the pressure sensor measured pressure from the electrical control and detected by comparing these courses with reference to tabular stored waveforms malfunctions of the pump unit or the valve and reported to at least one higher-level electrical control.

After starting the operation of the electro-fluidic unit at a temperature below a predetermined limit temperature T _G controls the electrical control ( 33 ) at least one of the electromagnets ( 4 . 4 ' ) with electrical pulses of a frequency greater than a predetermined cutoff frequency f _G until the temperature sensor ( 31 ) Measured temperature in the unit, the limit temperature T _G exceeds. The high-frequency control of at least one electromagnet no significant movements of the valve and / or the pump are generated, but the solenoid in question heats up and gives off heat to the working fluid. The limit temperature T _G depends on the working fluid and the cutoff frequency f _G is significantly (more than 30%) above the resonance frequency of the spring-mass system, which consists of a magnet armature and an associated return spring.

Application:

Aggregates of the type described are preferably used for monitoring of tank facilities, but can also be used where a reciprocating pump and a valve are to be applied together at low pressure.

list of figures

• 1 shows a section through an exemplary unit in the embodiment with a bellows in the pump unit and with a valve that closes in the energized state.
• 2 shows a schematic representation of the unit in the embodiment with a cylinder in the pump unit.
• 3 shows a section through an exemplary pump unit in detail

The exemplary embodiment of the electrofluidic aggregate ( 1 ) according to 1 contains an electrofluidic pump unit ( 2 ) and an electrofluidic valve ( 3 ), whereby both the pump unit ( 2 ) as well as the valve ( 3 ) of one electromagnet each ( 4 . 4 ' ) are actuated.
The pump set ( 2 ) and the valve ( 3 ) are on a same centerline ( 10 ) and use a storage bar ( 5 ) together for the mobile storage of a displacement device ( 6 ) of the pump set ( 2 ) actuating the first magnet armature ( 7 ) on the one hand and one of a group of closing bodies ( 8th ) actuating second magnet armature ( 9 ) of the valve ( 3 ) on the other hand.

The storage bar ( 5 ) is formed as a tube, the displacement means ( 6 ) of the pump set ( 2 ) with the inlet ( 11 ) of the aggregate ( 1 ) fluidly connects.
The possible alternative arrangement in which the tube connects the displacer with the outlet is not shown.

In the de-energized state of the valve ( 3 ) actuating electromagnets ( 4 ' ) connects the valve ( 3 ) bypassing the pump unit ( 2 ) the inlet ( 11 ) of the aggregate ( 1 ) with the outlet ( 13 ) of the aggregate ( 1 ) fluidically, said compound in the energized state of the electromagnet ( 4 ' ) is closed.

The possible alternative arrangement, in which in the energized state of the valve ( 3 ) actuating electromagnets ( 4 ' ) the valve ( 3 ) bypassing the pump unit ( 2 ) the inlet ( 11 ) of the aggregate ( 1 ) with the outlet ( 13 ) of the aggregate ( 1 ) fluidly connects, is not shown.

This in 1 illustrated pump unit ( 2 ) has a linear through the electromagnet ( 4 ) actuated bellows ( 20 ), which serves as a fluidic displacement device ( 6 ) acts.

The possible alternative equipment of the pump set ( 2 ) with a cylinder ( 21 ) and a piston ( 22 ) is schematic in 2 shown.

The pump set ( 2 ) according to 1 and 3 has an inlet valve ( 23 ), which consists of a valve seat ( 24 ) and a valve body ( 25 ), wherein the valve body ( 25 ) a highly elastic disc ( 26 ) and a centrally arranged holder ( 27 ) having.

In addition, the pump unit ( 2 ) according to 3 an outlet valve ( 28 ), which consists of a valve seat ( 24 ' ) and a valve body ( 25 ' ), wherein the valve body ( 25 ' ) a highly elastic disc ( 26 ' ) and a centrally arranged holder ( 27 ' ) having.

The electrofluidic aggregate ( 1 ) according to 2 contains a pressure sensor ( 30 ) and a temperature sensor ( 31 ), both with the outlet ( 13 ) of the aggregate ( 1 ) are connected.

LIST OF REFERENCE NUMBERS

1.

aggregate

Second

pump unit

Third

Valve

4th

electromagnet

5th

bearing rod

6th

Displacement device

7th

armature

8th.

closing body

9th

armature

11th

inlet

12th

Magnetic coil 13.Exhaust

14th

Return spring

20th

bellows 21 , cylinder

22nd

piston

23rd

intake valve

24th

valve seat

25th

valve body

26th

disc

27th

holder

28th

outlet valve

30th

pressure sensor

31st

temperature sensor

32nd

tank

33rd

Electric control

Claims (14)

Electrofluidic unit (1), at least one electrofluidic pump unit (2) and an electrofluidic valve (3) comprising, both the pump unit (2) and the valve (3) by a respective electromagnet (4, 4 ') are actuated, characterized characterized in that the pump unit (2) and the valve (3) are arranged on a same center line (10) and a bearing rod (5) together for the movable mounting of a first magnet armature (7) actuating a displacement device (6) of the pump unit (2). on the one hand and a second armature (9) of the valve (3) actuating a group of closing bodies (8) on the other hand. Electrofluidic aggregate (1) according to Claim 1 , characterized in that the bearing rod (5) is designed as a tube which fluidly connects the displacement device (6) of the pump unit (2) with one of the fluidic connections inlet (11) or outlet (13) of the unit (1). Electrofluidic unit (1) according to any one of the preceding claims, characterized in that in the de-energized state of the electromagnet (4 ') actuating the valve (3), the valve (3) bypassing the pump unit (2) fluidly connects the inlet (11) of the unit (1) with the outlet (13) of the unit (1), wherein said connection in the energized state of the electromagnet (4 ') is closed. Electrofluidic aggregate (1) according to one of Claims 1 to 2 , characterized in that in the energized state of the valve (3) actuating electromagnet (4 '), the valve (3) bypassing the pump unit (2) the inlet (11) of the unit (1) with the outlet (13) of the unit (1) connects fluidically, wherein said connection is closed in the de-energized state of the electromagnet (4 '). Electrofluidic unit (1) according to one of the preceding claims, characterized in that the pump unit (2) has a linearly through the electromagnet (4) directly or indirectly actuated bellows (20) which acts as a fluidic displacement means (6). Electrofluidic aggregate (1) according to one of Claims 1 to 4 , characterized in that the pump unit (2) has a fluidic displacement device (6), which consists of at least one cylinder (21) and a piston (22). Electrofluidic unit (1) according to one of the preceding claims, characterized in that the pump unit (2) has an inlet valve (23) which consists of a valve seat (24) and a valve body (25), wherein the valve body (25) has a highly elastic Disc (26) and a centrally disposed holder (27). Electrofluidic unit (1) according to one of the preceding claims, characterized in that the pump unit (2) has an outlet valve (28) which consists of a valve seat (24 ') and a valve body (25'), wherein the valve body (25 ' ) has a highly elastic disc (26 ') and a centrally disposed holder (27'). Electrofluidic unit (1) according to one of the preceding claims, characterized in that it contains a pressure sensor (30) which is connected to the outlet (13) of the unit (1). Electrofluidic unit (1) according to one of the preceding claims, characterized in that it contains a temperature sensor (31) which is connected to the outlet (13) of the unit (1). Method for operating an electrofluidic unit (1) containing at least one electrofluidic pump unit (2) and an electrofluidic valve (3), wherein both the pump unit (2) and the valve (3) by an electromagnet (4) or each an electromagnet (4, 4 ') are actuated, characterized in that a with the electro-fluidic unit (1) connected electrical control (33), the electromagnets (4, 4') so controls that • at the outlet (13) has a fluidic pressure difference is constructed by the electromagnet (4) of the pump unit (2) is clocked energized with the valve (3) closed, wherein the armature (7) the displacer (6) moves accordingly and wherein fluid is conveyed while the gas pressure in a connected tank (32) is increased or decreased, • the clocked energization of the electromagnet (4) of the pump unit is terminated and the valve (3) by energizing its electromagnet (4 ') ges • a pressure profile in a connected tank (32) is measured by a pressure sensor (30) connected to the outlet (13) or to the supply line to the tank (32) indicates the pressure in the tank (32) electrical control (33) is transmitted, wherein in the electrical control (33) the course of the pressure is recorded, • after a predetermined time Tv the measurement and recording of a second pressure curve is made, • the two pressure curves are compared with each other and from the difference the pressure in the tank (32) is reduced, the valve (3) is opened by the associated solenoid (4) is de-energized. Method for operating an electro-fluidic unit (1) according to Claim 11 characterized in that during each measurement and recording of the pressure in the tank (32) also the temperature of the fluid at the outlet (13) or in the supply line to the tank (32) is measured and recorded by means of a temperature sensor (31) When comparing the pressure curves, the temperature profiles using the general gas equation are also used to calculate a corrected course of the pressure curves. Method for operating an electro-fluidic unit (1) according to one of Claims 11 or 12 , characterized in that the electrical control (33) monitors the electro-fluidic unit to its intended function by both the course of energization of the electromagnet (4) of the pump unit (2) and the course of the pressure sensor (30) measured pressure of the electrical control (33) are recorded and by a comparison of said courses with reference to tabular stored waveforms malfunctions the pump unit (2) or the valve (3) discovered and reported to at least one higher-level electrical control. Method for operating an electrofluidic unit (1) according to one of the preceding method claims, characterized in that after a start of operation at a temperature below a predetermined limit temperature T _G, the electrical control (33) at least one of the electromagnets (4, 4 ') electrical pulses of a frequency greater than a predetermined limit frequency f _G so long drives until the measured temperature with the temperature sensor (31) exceeds the limit temperature T _G in the unit.

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